Templated growth of graphenic materials

ABSTRACT

A method is disclosed for producing graphenic materials by templated growth along a preformed graphenic material lattice edge, wherein at least one of the graphenic material or template is translated during growth of the graphenic material. A method for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a reactive carbon source in a fluid phase is also disclosed, wherein at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate. A method is also disclosed for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a carbon source in a fluid phase, wherein non-thermalized excited states are produced on the CNT substrate and at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.12/135,914 filed Jun. 9, 2008 which claims benefit and priority of U.S.patent application Ser. No. 60/943,041 filed Jun. 9, 2007, which ishereby incorporated by reference as if written herein in its entirety.

BACKGROUND

Carbon nanotubes (CNTs) are an allotrope of carbon having an exceedinglylong length-to-diameter ratio. These cylindrical carbon moleculespossess novel properties, including exceptional strength and uniqueelectrical properties, making them of substantial interest forapplications in diverse fields of nanotechnology, electronic devices,optical devices and materials science. Inorganic nanotubes are alsoknown. Efficient methods for production of CNTs is therefore an area ofintense research.

A number of techniques are available for synthesizing CNTs. Many methodsfor synthesizing CNTs produce mixtures of multi-walled carbon nanotubes(MWCNTs) and SWCNTs. For CNTs to be optimally utilized, methods forefficient production of SWCNTs having controlled properties, such aslength, diameter, chirality, and number of walls are desired. Further,efficient methods are desired to manipulate synthesized CNTs intomulti-nanotube arrays with controlled placement of the CNTs, which maybe used in electronic, optical and mechanical applications, such aselectronic devices.

SUMMARY

In the most general sense, the embodiments disclosed herein relate to amethod for producing a structured material through a process comprisedby 1) placing a preformed graphenic material substrate into contact witha templating structure, 2) providing a reactive source of atoms from afluid phase, 3) depositing atoms from the fluid phase to the preformedsubstrate and 4) translating at least one of the preformed substrate andthe templating structure during the depositing, while maintaining thecontact, so as to grow the preformed substrate in to the structuredmaterial.

In one aspect, the embodiments disclosed herein relate to a method forproducing a CNT, through a process comprised by 1) placing a preformedCNT substrate open on at least one end into proximity of a cylindricaltemplating structure, such that the CNT substrate contacts thetemplating structure and aligns with the templating structure in acoaxial fashion within thermal variation, 2) binding a CNT substrate andtemplating structure to separate inert supports capable of independenttranslation, 3) providing a reactive carbon source in a fluid phase, and4) depositing carbon from the fluid phase to the open end of a CNTsubstrate, wherein at least one of the CNT substrate or templatingstructure is translated during the depositing.

In another aspect, the embodiments disclosed herein relate to a methodfor producing a CNT, through a process comprised by 1) placing apreformed CNT substrate open on at least one end into proximity of acylindrical templating structure, such that the CNT substrate contactsthe templating structure and aligns with the templating structure in acoaxial fashion within thermal variation, 2) binding a CNT substrate andtemplating structure to separate inert supports capable of independenttranslation, 3) producing non-thermalized excited states in a CNTsubstrate lattice edge, and 4) depositing carbon from a fluid phase tothe open end of a CNT substrate, wherein at least one of the CNTsubstrate or templating structure is translated during addition ofcarbon to the CNT substrate.

The foregoing has outlined rather broadly the features of the presentdisclosure in order that the detailed description that follows may bebetter understood. Additional features and advantages will be describedhereinafter which form the subject of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present disclosure, and theadvantages thereof, reference is now made to the following descriptionsto be taken in conjunction with the accompanying drawings, in which:

FIG. 1 shows an embodiment of the co-axial arrangement of an inerttemplating structure and CNT substrate in the present disclosure.

FIG. 2 shows an embodiment of a winding mechanism in the presentdisclosure used to translate the CNT substrate.

FIG. 3 demonstrates an embodiment of a method whereby an array of CNTseeds can be produced from a single CNT of known type as described inthe present disclosure.

FIG. 4 shows an alternative embodiment for arraying CNTs in the presentdisclosure, whereby an array of CNT seeds is prepared on the surface ofa spooling mechanism from a single CNT.

FIG. 5 shows an embodiment of self-regulated growth of CNTs underelectrochemical deposition conditions.

FIG. 6 shows an embodiment of a CNT positional control system.

FIG. 7 shows an embodiment whereby multiple coaxial CNTs can be grownsimultaneously to form a beveled CNT tip.

DETAILED DESCRIPTION

In the following description, certain details are set forth, such asspecific quantities and sizes, to provide a thorough understanding ofembodiments disclosed herein. However, it will be understood by thoseskilled in the art that the present disclosure may be practiced withoutsuch specific limitations. In many cases, details concerning suchconsiderations and the like have been omitted inasmuch as such detailsare not necessary to obtain a complete understanding of the presentdisclosure and are within the skills of persons of ordinary skill in therelevant art.

The present disclosure generally relates to a method for providingtemplated growth of structured materials, which may include a graphenicmaterial. The templated growth may be along pre-existing graphenicmaterial lattice edges under influence of a templating structure.Graphenic materials are formed from one or more graphene sheets anddemonstrate comparable chemical reactivity to graphene. Graphenicmaterial lattices may include both substitutional and interstitialatoms. In the present disclosure, a preformed graphenic substrate and atemplating structure are brought into proximity of one another, suchthat the preformed graphenic substrate and templating structure are incontact. The contact may be a reduced energy contact, wherein thecontacted system is reduced in energy compared to the two separatedbodies. A reactive source of atoms is provided in a fluid phase, andatoms are deposited to the graphenic substrate from the fluid phaseunder influence of the templating structure, while at least one of thepreformed graphenic substrate and templating structure is translatedduring the depositing. Deposition may occur at a lattice edge of thesubstrate. The reactive source of reactive atoms may be provided aseither a monoatomic or polyatomic chemical species. Translation isembodied as either a linear motion or a spooling motion where thegraphenic material is wound on to a spool as it is grown. The method mayalso be practiced wherein more than one preformed graphenic substrateand a single templating structure per preformed graphenic substrate areused to simultaneously grow more than one new graphenic material. Oneskilled in the art will recognize that graphene, graphenic materials,CNTs, and like structures possess similar chemical reactivity, and themethods of the present disclosure may be used interchangeably fortemplated growth on these entities through minimal modifications of thedisclosure provided herein. Generation of reactive atoms in the fluidphase may be accomplished herein by several different methods, theadvantages of which for a given application will be easily recognizableto those of skill in the art.

When the templated growth of graphenic materials is practiced asdescribed herein, a number of advantages are realized for the productionof graphenic materials, CNTs, and related structured materials. CNTsproduced by this method may be SWCNTs or MWCNTs. DWCNTs are exemplary ofMWCNTs. Templated growth accomplishes production of graphenic materialson a pre-existing substrate, wherein van der Waals and Pauliinteractions between the template structure and the graphenic substratedefine the topology of the graphenic material produced. In particular,production of CNTs under templated growth conditions allows CNTs to beproduced that are free of lattice defects and maintain the chirality ofthe template CNT. Another advantage of the present method is that ifeither the templating structure, graphenic substrate, or both aretranslated during addition of atoms to the graphenic substrate,graphenic materials of arbitrary length may be produced from a fixedlength templating structure, provided that the graphenic substratemaintains contact with the templating structure. The disclosure hereindescribes a method to produce CNTs of arbitrary length from a fixedlength templating structure. The CNTs produced as described herein havetheir positions defined at two fixed points, such that the CNTs may beadvantageously handled with high precision through mechanicalmanipulation methods known to those having skill in the art. The methodsdescribed herein may be readily conducted in parallel to provide two-and three-dimensional arrays composed of multiple CNTs.

While most of the terms used herein will be recognizable to those havingskill in the art, the following definitions are nevertheless put forthto aid in the understanding of the present disclosure. It should beunderstood, however, that when not explicitly defined, terms should beinterpreted as adopting a meaning presently accepted by those of skillin the art.

“Graphene,” as defined herein, is a single sheet of carbon atomscovalently bonded in a two-dimensional hexagonal lattice. A graphenesheet may be viewed as a crystal basal plane bounded by termination ofthe crystal at a lattice edge.

“Graphite,” as defined herein, is an ordered collection of graphenesheets stacked on top of one another to form a crystalline structurewith van der Waals forces interacting between the graphene sheets andcovalent bonding forces interacting within the graphene sheets. Althoughthis definition is true for perfect crystals, in reality graphite has asmall percentage of covalent linkages between the graphene sheets.

“Template or templating structure,” as defined herein, is an entity thatdetermines the geometry of produced graphenic materials by providing areduced energy pathway for growth of said graphenic materials. Theinteraction of the graphenic lattice and template is such that nopersistent covalent bonding is produced between the two. Suchinteraction is achieved through non-covalent forces, including, but notlimited, to van der Waals and Pauli interactions.

“Reduced energy contact,” as defined herein is the condition whereinnon-covalent forces, including, but not limited to, van der Waals andPauli exclusion forces, lead to a local potential minima as two bodiesare brought to an interatomic distance wherein the potential energybetween them is near this minima. In the reduced energy contact, thecontacted system is reduced in energy compared to the energy of the twoseparated bodies. The interatomic distance of the reduced energy contactis defined with respect to a spacing between nuclei.

“Array,” as defined herein is a two-dimensional or three-dimensionalarrangement of graphenic material structures.

“Pirhana,” as defined herein is a mixture of sulfuric acid and hydrogenperoxide.

The graphenic materials in the present disclosure may constitutegraphene, multiple layers of graphene, all-carbon graphenic materials,non-carbon graphenic materials, and graphenic materials having bothcarbon and non-carbon atoms. Graphenic materials are particularlyembodied in one instance by CNTs. Graphenic materials may be utilized toform graphenic substrates suitable for templated growth. Graphenicmaterials may be composed of hexagonal lattices of carbon. Graphenicmaterials are illustrative of substrates herein. It will be understoodthat other substrate materials which form hexagonal lattices, such astwo-dimensional boron nitride are contemplated. Further, materials whichform hexagonal lattices mixed with another geometric shape (e.g atriangular lattice), such as elemental boron, are contemplated. Oneskilled in the art will recognize that simple modifications of themethods described herein may be utilized to template non-carbon atoms onto all-carbon graphenic substrates or carbon atoms on to non-carbongraphenic substrates.

The templating structures in the present disclosure provide a reducedenergy pathway for growth of graphenic materials having controlledgeometrical properties on to a pre-existing graphenic substrate. Theattractive interaction of the graphenic substrate to the templatingstructure does not produce persistent covalent bonding between the two.Intimate physical contact between the graphenic substrate and thetemplating structure ensures efficient transfer of structural featuresfrom the templating structure to the newly produced graphenic materiallattice edge, thus eliminating lattice edge defects and providing thesame chirality to the lattice edge as embodied in the templatingstructure. The lack of covalent bonding between the templating structureand graphenic substrate allows a wide variety of graphenic materialshaving known geometry to be produced through simple modifications of thedisclosure provided herein.

Atoms are added to the graphenic substrate/template structural interfacefrom a fluid phase, which provides a source of reactive carbon or likeatoms which form graphenic lattices. One skilled in the art willrecognize that the exact chemical mechanism whereby addition of atoms,in particular carbon atoms, to the graphenic substrate occurs may differdepending on the chosen fluid phase atom source. The fluid phase may bea gaseous phase, such as a vapor phase. The vapor phase entity fromwhich the reactive atom species arises may be a solid, liquid, or gas inits standard state at room temperature. The suitability of a particularvapor phase reactive atom source toward a given application will dependon conditions specific to the application and be evident to one havingskill in the art. The choice of a particular reactive atom source for agiven application should not be considered limiting when other reactiveatom sources may be utilized within the spirit and scope of thedisclosure.

The fluid phase may be a carbon-containing gas, wherein carbon atoms aredeposited on to the graphenic substrate by chemical vapor deposition(CVD). One skilled in the art will recognize that the gas phasecarbon-containing compounds may derive from gases, liquids, or solidshaving high vapor pressures, wherein the reactive carbon atom source isgenerated from these gas phase compounds by known methods. Suitablecarbon-containing compounds for generating a gas phase carbon atomsource may include, but are not limited to, at least one member of thegroup consisting of methane, ethane, propane, butane, isobutane,ethylene, propene, 1-butene, cis-2-butene, trans-2-butene, isobutylene,acetylene, propyne, 1-butyne, 2-butyne, benzene, toluene, carbonmonoxide, methanol, ethanol, 1-propanol, 2-propanol, 1-butanol,2-butanol, 2-methyl-2-propanol, cyclopropane, cyclobutane, acetonitrile,propionitrile, butyronitrile, acetone, butanone, formaldehyde,acetaldehyde, propionaldehyde, and butyraldehyde.

The gas phase carbon atom source may be a molecule in an excited state,wherein increased reactivity with the graphenic substrate may beachieved. When the vapor phase contains an excited state species, thecollision rate of the excited state species in the vapor phase may beselected to be sufficiently low so as to avoid generation of unwantedreactive species from non-excited state vapor phase molecules. In someembodiments, the excited state is a vibrational excited state. In otherembodiments, the excited state is a radical state. Suitable radicalstates may include, but are not limited to, C₂H and C₂H₃. In still moreembodiments, the excited state is an excited electronic state. Arepresentative excited electronic state is non-dissociatively excitedacetylene, which has been excited by electromagnetic radiation having awavelength of about 220 nm, although other excited electronic states canalso be utilized within the spirit and scope of the disclosure. Theforegoing list of excited state species is meant to be representative ofexcited state entities suitable for bringing the disclosure to practiceand should not be considered limiting for this purpose. One skilled inthe art will recognize that an energetically excited state specieshaving suitable reactivity for a given application may be generated by anumber of techniques and utilized equivalently in the spirit and scopeof the methods described herein.

The fluid phase may also be a carbon-containing liquid. Suitablecarbon-containing liquids include, but are not limited to, at least onemember of the group consisting of benzene, toluene, xylenes, and likeliquids having high carbon content.

The fluid phase may also be a molten metal containing a dissolved carbonsource, wherein the molten metal pool is in physical contact with thegraphenic substrate. The molten metal source is selected from at leastone metal known to provide significant solvation for carbon. Said metalsmay be chosen from periodic table groups 1-12, the lanthanide elements,and alloys thereof. In certain embodiments, suitable metals include, butare not limited to, at least one member of the group consisting of Fe,Co, Ni, Au, and alloys thereof. Non-metallic elements including, but notlimited to Si and P, may optionally be included in the melt to modifythe effective carbon saturation (reactivity) and deposition potential.Sulfur and copper are particularly known to decrease the surface energyof carbon-containing molten metal melts, and these elements may alsooptionally be included. One skilled in the art will recognize thatchoice of a particular metal solvent system for a given application willbe governed by a number of factors, including, but not limited to,melting point, equilibrium solubility of carbon in the molten metal, andreactivity of the carbon species in the chosen molten metal solvent. Ina molten metal bath, direct solvation of carbon allows growth ofgraphenic materials to take place as a quasi-equilibrium thermodynamiccrystal growth process controlled by melt supersaturation. The level ofsupersaturation determines the growth mode from solution in accordancewith the Gibbs free energy of carbon in solution versus carbon bound ina lattice. By maintaining the carbon level in the molten metal solventat slightly supersaturated conditions, growth of graphenic materialsfrom solution is driven to pre-existing graphenic material lattice edgesites.

The dissolved carbon source in the molten metal bath may be introducedfrom a vapor phase carbon species in certain instances. One skilled inthe art will recognize that the vapor phase carbon-containing speciesmay derive from gases, liquids, or solids having low vapor pressures.Said carbon-containing compounds may contain at least one additionalelement besides carbon, which may include, but not be limited to, thegroup consisting of hydrogen, oxygen, sulfur, nitrogen, fluorine,chlorine, bromine, iodine, silicon and phosphorus. It is well known inthe art of carbon-containing molten metal solutions that the presence ofother atoms in solution may affect the carbon activity and growth modeof carbon deposition. For example, other elements may reduce the surfacetension of the molten metal bath and lower the interfacial energybetween the metal melt and non-wetting surfaces it contacts. Sulfur andcopper are particularly known to decrease the surface energy ofcarbon-containing molten metal melts, and these elements may optionallybe included in the molten metal baths described herein. Non-metallicelements including, but not limited to Si and P, may optionally beincluded in the melt to modify the effective carbon saturation(reactivity) and deposition potential. Suitable carbon-containingcompounds for generating a vapor phase carbon source may include, butare not limited to, at least one member of the group consisting ofmethane, ethane, propane, butane, isobutane, ethylene, propene,1-butene, cis-2-butene, trans-2-butene, isobutylene, acetylene, propyne,1-butyne, 2-butyne, benzene, toluene, carbon monoxide, methanol,ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol,2-methyl-2-propanol, cyclopropane, cyclobutane, acetonitrile,propionitrile, butyronitrile, acetone, butanone, formaldehyde,acetaldehyde, propionaldehyde, and butyraldehyde.

The vapor phase may optionally contain an inert diluent gas in additionto the carbon-containing source, such that the molten metal bath isexposed concurrently to both the gas phase carbon-containing compoundand inert diluent gas. Suitable diluent gases may include, but are notlimited to, at least one component selected from the group consisting ofhelium, argon, and nitrogen. The vapor phase may optionally contain anetchant component in addition to the carbon-containing source, such thatthe molten metal bath is exposed concurrently to both the gas phasecarbon-containing compound and etchant vapor. In certain cases, it isdesirable that the vapor phase contain both the etchant component anddiluent gas along with the carbon-containing compound, such that themolten metal bath is concurrently exposed to all three substances.Suitable etchants include, but are not limited to, at least onecomponent selected from the group consisting of water, carbon dioxide,ammonia, and hydrogen.

In certain embodiments, the carbon source in the molten metal bath maybe a solid carbon source in direct contact with the bath. Such a carbonsource may be dissolved preferentially over the carbon substrate.Preferential dissolution of the carbon source may be achieved throughvarious techniques, such as through applied electrical potentials or byconstructing the solid carbon source from a less energetically stablecarbon form, such as amorphous carbon.

In certain embodiments, one or more graphenic materials may be grownconcurrently from individual, isolated carbon-containing molten metalbaths.

One or more metal atoms may be attached to the graphenic materiallattice edge in certain embodiments. In high temperature gas phasegrowth of CNTs, some metal atoms are known to function as effectivecatalyst species for promoting CNT growth. Bonding of at least onecatalytic metal atom to the graphenic material lattice edge may likewiseenhance chemical reactivity of the graphenic substrate toward templatedgrowth along the graphenic material lattice edge. Suitable metal atomsmay include, but are not limited to, at least one member of periodictable groups 3-12, the lanthanide elements, and combinations thereof.The catalytic metal atoms may be bound to the graphenic material latticeedge through methods resulting in a controlled number and density ofmetal atoms on the lattice edge.

In some embodiments, catalytic metal atoms are introduced to thegraphenic material lattice edge by coupling reactions between mixturesof metal atom bearing species and non-metal bearing species havingcomparable reactivity toward reactive groups on the graphenic materiallattice edge. The density of metal atom incorporation on the graphenicsubstrate may be controlled simply by adjusting the ratio ofmetal-bearing to non-metal bearing species in the coupling reaction.Suitable metal atom bearing species may include, but are not limited to,functionalized metallocenes (eg., ferrocene), metal-EDTA derivatives,and related organometallic and metal-ligand complexes. Non-metal bearingspecies having comparable reactivity to these specific examples mayinclude the functionalized non-metallated ligand or similar compoundhaving comparable reactivity toward the reactive groups on the graphenicmaterial lattice edge. One skilled in the art will recognize that a widevariety of non-metallated compounds having like reactive functionalityto the functionalized metal bearing compound may be used to control thedensity of metal atom deposition. These competing non-metallated speciesmay bear no structural resemblance to the metallated species in certaininstances, while still maintaining comparable chemical reactivity to theparent metal bearing compound. A convenient functional group forattaching the metal bearing species and their non-metal bearingcounterparts to graphenic material lattice edges is a carboxylic acid,although other functional groups may be manipulated to couple withgraphenic material lattice edges through methods known to those skilledin the art. In the instance where the reactive functional group on themetal-bearing compound is a carboxylic acid, the metal bearing speciesmay be attached to surface graphenic material lattice edge OH groups viaan esterification reaction through various coupling reactionmethodologies known to those skilled in the art. The range of reactionsutilized to couple to the graphenic material lattice edge is not limitedto esterifcation, and other coupling strategies including, but notlimited to, alkoxylation and amidation are viable alternatives forlinking metal atoms to the graphenic material lattice edge.

Ligand binding sites on the graphenic material lattice edge may bereacted with metal ion solutions having variable concentration and pH.The ligand binding sites may be pre-existing in certain embodiments,including, but not limited to, terminal carboxylic acid moieties at thegraphenic material lattice edge. A suitable ligand may also besynthesized on the graphenic material lattice edge. One skilled in theart will recognize that certain metal ion solutions will require pH andreaction temperatures having values within a defined range toefficiently bind to the surface ligands. Furthermore, for a given metalsalt, a finite attainable concentration range and chemical compatibilityprofile will be realized due to the innate physical properties of themetal salt.

An aspect of the present disclosure is the translation of at least oneof the graphenic substrate or templating structure during addition ofcarbon or like graphenic atoms to the graphenic substrate. As practicedherein, the graphenic substrate and templating structure are bound toinert supports, which are capable of independent motion and utilized totranslate the graphenic substrate, templating structure, or both,wherein the translation is coplanar to the growth of the graphenicsubstrate. In certain embodiments, the direction of translation isanti-parallel to the direction of graphenic substrate growth. In someembodiments, the support to which the graphenic substrate is bound isindependently translated. In other embodiments, the support to which thetemplating structure is bound is independently translated. In stillfurther embodiments, both supports are translated concurrently. Whenboth supports are translated concurrently, the supports may betranslated either toward one another or away from one another. In someembodiments, the supports are concurrently translated in oppositedirections. In other embodiments, the supports are concurrentlytranslated in the same direction. The supports may be moved linearly orrotated in a spooling motion to affect translation of the graphenicsubstrate and templating structure. As a consequence of the translationcapability, graphenic materials produced through templated growth on thegraphenic substrate are permitted to remain in contact with thetemplating structure during addition of atoms to the graphenicsubstrate, while not damaging the graphenic material during thetranslation process due to minimal sliding friction between the twostructures. This arrangement beneficially allows templating structuresof finite physical dimension to direct the growth of graphenic materialsto an arbitrary length. In certain embodiments wherein the templatingstructure, graphenic substrate, or both the templating structure andgraphenic substrate are translated, the rate of translation is matchedby the rate of addition of atoms to the graphenic substrate. If duringaddition of atoms to the graphenic substrate, the rate at which thetemplating structure and graphenic substrate are translated apart is tooslow, then growth of the graphenic substrate will eventually contact theinert support to which the templating structure is bound Likewise, ifduring addition of atoms to the graphenic substrate, the rate at whichthe templating structure and graphenic substrate are translated apart istoo rapid, then growth of the graphenic material will not keep pace withthe rate of translation, and the graphenic substrate will eventuallybecome disconnected from the templating structure. In the embodiment oftranslation described herein, the direction of translation is paralleland coplanar to the plane of growth of the graphenic material. Incertain embodiments, the direction of translation is anti-parallel tothe direction of graphenic substrate growth. In still furtherembodiments, translation of the graphenic substrate, templatingstructure, or both the graphenic substrate and templating structure isaccomplished through a winding motion, wherein the graphenic material iswound on to a spool mechanism as it is grown. In certain embodiments,the spool mechanism may be optionally translated parallel to the axis ofwinding at the same time it is wound.

The rate of carbon atom addition to the graphenic substrate may becontrolled in several different manners. In one embodiment, the growthrate of carbon atom addition to the graphenic substrate is controlled byspatial modulation of an electromagnetic radiation field used to produceexcited state carbon species in the fluid phase or used to createreactive excited states at the lattice edge. The population of excitedstate species may be controlled by the physical location and intensityof the electromagnetic radiation field, such that a population ofexcited state species may be produced at the graphenic material latticeedge at a desired level to give a pre-determined rate of atom additionto the graphenic substrate. In embodiments where there is translation ofthe graphenic substrate, the templating structure, or both the graphenicsubstrate and templating structure, the radiation field is modulatedabout the axis along which translation occurs, such that as thegraphenic substrate is translated, the population of excited statespecies at the lattice edge changes in proportion to the distancebetween the spatial illumination and the lattice edge. Spatialmodulation may be utilized to control the growth rate of carbon atomaddition to the graphenic substrate so that the rate of translation ismatched by the growth rate of carbon atom addition. A benefit ofspatially modulated growth of graphenic materials is that deviations inthe growth rate are self-correcting. As such, when the translation rateoutpaces or falls behind the growth rate, the growth rate adjusts tomatch. In one embodiment of this technique, the exciting radiation is inthe ultraviolet region of the electromagnetic spectrum. In someembodiments, the ultraviolet radiation has an energy of about 3 eV toabout 100 eV. In further embodiments, the ultraviolet radiation has anenergy of about 3.1 eV to about 12 eV. In still further embodiments, theultraviolet radiation has an energy of about 3.5 eV to about 5.5 eV. Itwill be understood by one skilled in the art that depending on thespecific molecule being taken to an excited state in a givenapplication, other forms of electromagnetic radiation and excitationwavelengths can be utilized in the spirit and scope of the disclosure toform the spatially modified radiation field.

In another embodiment to control the rate of carbon atom addition to thegraphenic substrate, a gradient may be produced in the chemicalpotential of the carbon-containing vapor phase. The gradient may beinfluenced by a gradient in the carbon concentration and/or carbonactivity. When the gradient is produced in the chemical potential of thecarbon-containing vapor phase, the carbon-containing vapor is deliveredparallel to the direction of graphenic substrate and the direction oftranslation. In some embodiments, the vapor phase optionally containsone or more inert diluent gases or one or more etchant components inaddition to the carbon source. The gradient in chemical potential of thecarbon-containing vapor phase exists along the common axis created bythe graphenic substrate growth and the direction of translation. Thegradient in carbon-containing vapor phase chemical potential ismaintained in these embodiments through independent modulation of thecarbon source comprising the vapor, inert diluent gas in the vapor, andetchant component in the vapor.

A gradient in carbon chemical potential of molten metal baths may alsobe utilized to control the growth rate of the graphenic substrate. Inone embodiment of the present disclosure, a bulk molten metal bath ismaintained on one side of a wall of refractory material having aplurality of small (<10 μm) holes penetrating through the wall. In otherembodiments, the molten metal bath is maintained on both sides of thewall. In some embodiments, the molten metal bath resides in theplurality of small holes. The wall thickness is sufficient to 1)maintain mechanical integrity, 2) allow the graphenic substrate/templatesystem to reside in the hole, and 3) allow the growing graphenicsubstrate to extend out of the hole. In embodiments having the moltenmetal bath maintained on one side of the wall, on the side of the wallopposite the molten metal bath, templating structures are bound to aninert support. The side of the wall housing the bulk molten metal bathis maintained in an atmosphere rich in etchant component, and on theopposite side of the wall is maintained in an atmosphere ofcarbon-containing source gas. One skilled in the art will recognize thatthis spatial arrangement produces a gradient of carbon chemicalpotential in the molten metal baths at the point through which the bulkmolten metal penetrates the wall. In a further embodiment, the carbonchemical potential gradient may be controlled through the rate at whichthe carbon-containing source gas is delivered. In a still furtherembodiment, the diffusion rate of the carbon-containing source into themolten metal bath produces a carbon chemical potential gradient. Thecarbon-containing species may include, but is not limited to, at leastone of the components selected from the group consisting of methane,ethane, propane, butane, isobutane, 1-butene, cis-2-butene,trans-2-butene, isobutene, ethylene, propene, acetylene, propyne,1-butyne, 2-butyne, benzene, toluene, carbon monoxide, methanol,ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol,2-methyl-2-propanol, cyclopropane, cyclobutane, acetonitrile,propionitrile, butyronitrile, acetone, butanone, formaldehyde,acetaldehyde, propionaldehyde, and butyraldehyde. Inert diluent gasesmay include, but are not limited to, at least one component selectedfrom the group consisting of helium, argon, and nitrogen. The etchantcomponent may include, but is not limited to, at least one componentselected from the group consisting of water, carbon dioxide, ammonia,and hydrogen. One skilled in the art will recognize that these specificexamples are meant to be illustrative of the disclosure herein, anddepending on the requirements for a specific application, differentcomponents or mixtures of components not explicitly cited may be used tooperate within the spirit and scope of the disclosure. In certain otherembodiments of molten metal baths described herein, one or more moltenmetal baths are maintained in pits on a refractory surface, wherein aspatial gradient of carbon chemical potential exists in the molten metalbaths as a result of modulating the rate at which carbon-containingvapor is introduced to the molten metal baths and diffusion of carboninto the molten metal solvent takes place. In all of these embodiments,the gradient of carbon chemical potential in the metal bath allows therate of carbon atom addition to the graphenic substrate to be matched tothe rate of translation.

The present disclosure also describes in detail herein a method forproducing CNTs, through a process that includes the steps of 1) placinga preformed CNT substrate open on at least one end into proximity of acylindrical templating structure, such that the CNT is coaxially alignedwith the templating structure and contacts the templating structurewithin thermal variation, 2) binding the CNT substrate and templatingstructure to separate inert supports capable of independent translation,3) providing a reactive carbon source in a fluid phase, and 4)depositing carbon from the fluid phase to the open end of the CNTsubstrate where the CNT substrate lattice edge contacts the cylindricaltemplating structure while at least one of the CNT substrate ortemplating structure is translated during the depositing. When thedisclosure is practiced in this manner, carbon atoms may be incorporatedon the existing CNT substrate under the influence of the cylindricaltemplating structure to prevent the formation of lattice defects duringgrowth, including end capping of the CNT with carbon atoms.

In some embodiments, the cylindrical templating structure contacts theinterior of the CNT substrate. In other embodiments, the cylindricaltemplating structure contacts the exterior of the CNT substrate. Inembodiments wherein the templating structure contacts the interior ofthe CNT, the templating structure may extend beyond either end of theCNT substrate. In further embodiments wherein the cylindrical templatingstructure contacts the interior of the CNT substrate, the templatingstructure is a CNT having a diameter smaller than that of the CNTsubstrate, such that the templating CNT contacts the interior of the CNTsubstrate. When the disclosure is practiced in this manner, mechanicalindependence of the growing CNT substrate from the CNT templatingstructure is ensured. Likewise, physical and chemical stability of theCNT templating structure to the growth environment is maintained, andcarbon atom deposition on the CNT templating structure is suppressed anddirected primarily to the CNT substrate.

The CNT templating structure and CNT substrate may be attached toindependent supports, which are inert toward the conditions utilized forfluid phase growth of CNTs. Suitable support materials depend upon thegrowth fluid environment. For example, alumina, magnesia or acombination thereof is well suited for molten transition metal baths Thearrangement of the CNT templating structure, CNT substrate and inertsupports for each is shown in FIG. 1. The supporting surface attachmentpoints for the CNT templating structure 101 and CNT substrate 102 areopposite the point of contact 103 between the CNT templating structurewith the CNT substrate along the common cylindrical axis created by 101and 102. The supports 100 and 105 to which CNT templating structure 100and CNT substrate 105 are attached are capable of independent motion,such that both the CNT templating structure 101 and CNT substrate 102may be translated by motion of the supports to which they are attached.In some embodiments, the support to which the CNT substrate is bound isindependently translated. In other embodiments, the support to which theCNT templating structure is bound is independently translated. In stillfurther embodiments, both supports are translated concurrently. Incertain embodiments, translation of the CNT substrate, CNT templatingstructure, or both the CNT substrate and CNT templating structure isaccomplished through a winding motion, wherein the CNT substrate iswound on to a spool mechanism as it is grown. One embodiment of such aspooling mechanism for translation of the CNT substrate is shown in FIG.2. CNT substrate 203 is translated from CNT templating structure 201,which is attached to inert support 200. CNT substrate 203 is drawn on tospooling mechanism 204, which is rotated in direction 206 to wind CNTsubstrate 203 on to the spooling mechanism. In certain embodiments, thespool mechanism may be optionally translated parallel to the axis ofwinding at the same time it is wound. As a consequence of thistranslation capability, CNTs produced through templated growth on theCNT substrate are permitted to remain in contact with the CNT templatingstructure during addition of carbon atoms to the CNT substrate, whilenot damaging either CNT during the translation process due to minimalsliding friction between the two structures. This arrangementbeneficially allows CNT templating structures of finite physicaldimension to direct the growth of CNTs to an arbitrary length.

The methods disclosed herein may be utilized to simultaneously producemore than one CNT. A two-dimensional or three-dimensional array of CNTsubstrates and CNT templating structures may be produced from a CNT ofknown type through steps comprising 1) positioning the CNT of known typeon an inert surface in a known configuration and 2) cutting the CNT ofknown type into individual CNT/coaxial CNT templating structures. TheseCNT ‘seeds’ may then be manipulated and grown through templated additionof carbon to the CNT substrate using any of the methods describedherein. In some embodiments of this method, the CNTs are all of knownlength. In other embodiments of this method, the CNTs are all in knownpositions and may be manipulated with mechanical precision. Arrayed CNTsand particularly SWCNTs may be particularly useful for nanoscopicelectronic devices such as integrated circuits and electronic memory.Two-dimensional arrays may be placed on an electronic device withnanoscale precision, wherein a precise spacing between the CNTs exists.In other applications, arrays may be engineered to act as “word-bit”lines in a memory device.

Methods are disclosed herein for positioning CNT substrates and CNTtemplating structures. A CNT substrate/CNT template pair may bepositioned coaxially. A plurality of CNT substrate/CNT template pairsmay be positioned in an array. It will be understood that methods ofpositioning CNT substrates and CNT templating structures areillustrative of placing a preformed substrate in contact with atemplating structure, wherein the preformed substrate and templatestructure are each CNT-based. This in turn is illustrative of placing apreformed substrate in contact with a templating structure.

According to an embodiment, a method for positioning is illustratedschematically in FIG. 3, wherein CNT substrates and CNT templatingstructures may be positioned by steps comprising 1) preparing a SWCNT ofknown length held at each end and suspended in free space, 2) opening atleast one end of the SWCNT, 3) filling the open SWCNT with fullerenessuch that the fullerenes are in contact within the SWCNT (structure300), 4) polymerizing the fullerenes to make a second CNT concentric toand inside the SWCNT, 5) placing the resultant DWCNT 301 on a suitablesurface in a known configuration, which may be a parallel configuration,through methods such as suspending the DWCNT 301 in a photosensitivepolymer above a transparent surface in a known configuration, 6) cuttingDWCNT 301 in regions 302 to leave an array of DWCNT 303, which may be aparallel array, 7) performing photolithography to pattern a maskinglayer 304, such as a refractory metal oxide layer, on one end of theDWCNT array, 8) etching the exposed ends of the DWCNTs to leave exposedSWCNTs 305 and masked DWCNTs 306, 9) removing the masking layer 304, and10) bonding each end of the resultant DWCNT/SWCNT array to inertsupports 307 and 308, which are capable of independent translation. Theresultant CNT ‘seeds’ may then be manipulated and grown throughtemplated addition of carbon to the CNT substrate using any of themethods described herein. The de novo growth of CNTs inside an existingCNT via polymerization of fullerenes is commonly known to those skilledin the art as the ‘peapod coalescence’.

In another embodiment of this method, one or more MWCNTs are suspendedin a photosensitive polymer above a transparent surface.Photolithography is then performed to pattern metal/ceramic contactsover each MWCNT at two places. The MWCNTs are then held suspendedbetween the metal/ceramic contact points when the structure is inverted.The inverted structure is coated with a photoresist substance, which isthen removed around only one of the metal/ceramic contact points perMWCNT to expose the outer layer of each MWCNT at each point. The outerlayer of the MWCNTs is opened by methods used to damage CNTs, such asfluorination, light oxidation with singlet oxygen or ozone, electricalburnout methods, or controlled etching using oxidizing baths (ie.,piranha, nitric acid, nitric acid/sulfuric acid). One skilled in the artwill recognize that these methods are not necessarily an exhaustivecompilation of methods capable of opening CNTs, and methods notexplicitly listed remain within the spirit and scope of the disclosure.Following opening of the outer CNTs, the open ends of the CNTs areetched using methods known to those skilled in the art, until the openends of the CNTs are at the desired point between the metal/ceramiccontacts. Suitable etching methods include, but are not limited to,hydrogen etching, low temperature piranha etching, and CO₂ etching. Thestructure is thereafter inverted again and aligned and bonded to twoseparate supports. Carbon atoms are then deposited on to the open end ofthe resultant CNT substrates from a fluid phase carbon source as atleast one of the CNT substrate or the CNT templating structure istranslated.

In yet another embodiment of the present disclosure, as illustrated inFIG. 4, a CNT substrate 402 and CNT templating structure 401 bound toinert support 400 may be positioned by steps comprising 1) wrapping CNTsubstrate 402 open on at least one end around a spool mechanism 404,wherein the spool is rotated in direction 406 to draw the CNT substrate402 on to the spool while the spool is simultaneously translated indirection 405 parallel to the winding axis, thereby winding the CNTsubstrate 402 on to the spool 404 to form a helical structure with knownpitch, 2) filling the open CNT on the spool with fullerenes such thatthe fullerenes are in contact within the CNT, 3) polymerizing thefullerenes to make a second CNT inside the original CNT, 4) performingphotolithography to cut the CNT into individual CNT segments 408 whileremoving CNT segments 407, wherein CNT segments 408 are aligned inparallel, 5) performing additional photolithography on the outer CNT ofeach individual CNT segment 408, wherein the inner CNT extends beyondthe outer CNT, 6) transferring the individual CNT segments to a surfacesuitable for CNT growth, wherein the CNTs segments remain parallel andinner/outer CNTs remain coaxial during the transfer process, and 7)bonding the inner and outer CNTs from each segment to supports that canbe independently translated. The aligned CNT ‘seeds’ and CNT templatingstructures may thereafter be utilized to grow CNTs using any of themethods described herein. In alternative embodiments of the alignmentprocess, the second CNT may be grown following photolithography to cutthe CNT into individual CNT segments 408. In another alternativeembodiment of the alignment process, the second CNT may be grownfollowing transfer of CNT segments 408 to the surface suitable for CNTgrowth.

At least one metal atom may be optionally bonded to the open end of theCNT substrate. In certain embodiments, the metal is selected periodictable groups 3-12, the lanthanide elements, and combinations thereof.Bonding of one or more metals is known to enhance the chemicalreactivity of CNT substrates toward addition of carbon atoms. Thepresent disclosure describes methods whereby catalytic metal atoms maybe attached to the CNT lattice edge in controlled number and density. Insome embodiments, metal deposition to the CNT lattice edge is affectedby electrochemical deposition of suitable metal precursors. Variablessuch as time- or current-limited voltage pulses and solutionconcentration of metal species may allow electrodeposition to be carriedout at variable rates for a given voltage in order to control the metaldensity on the CNT lattice edge. In other embodiments, metal atoms areattached to the CNT lattice edge by coupling reactions between mixturesof metal atom bearing species and non-metal bearing species ofcomparable reactivity with reactive groups on the CNT lattice edge. Thedensity of metal atom incorporation on the CNT lattice edge may becontrolled simply by adjusting the ratio of metal-bearing to non-metalbearing species in the coupling reaction. Suitable metal atom bearingspecies may include, but are not limited to, functionalized metallocenes(e.g., ferrocene), metal-EDTA derivatives, and related organometallicand metal-ligand complexes. Non-metal bearing species having comparablereactivity to these specific examples may include the functionalizednon-metallated ligand or similar compound having comparable reactivitytoward the reactive groups on the CNT lattice edge. One skilled in theart will recognize that a wide variety of non-metallated compoundshaving like reactive functionality to the functionalized metal bearingcompound may be used to control the density of metal atom deposition.These competing non-metallated species may bear no structuralresemblance to the metallated species in certain instances, while stillmaintaining comparable chemical reactivity to the parent metal bearingcompound. A convenient functional group for attaching the metal bearingspecies and their non-metal bearing counterparts to CNT lattice edges isa carboxylic acid, although other functional groups may be manipulatedto couple with CNT lattice edges through methods known to those skilledin the art. In the instance where the reactive functional group on themetal bearing compound is a carboxylic acid, the metal bearing speciesmay be attached to surface CNT lattice edge OH groups via anesterification reaction through various coupling reaction methodologiesknown to those skilled in the art. The range of reactions utilized tocouple to the CNT material lattice edge is not limited to esterifcation,and other coupling strategies including, but not limited to,alkoxylation and amidation are viable alternatives for linking metalatoms to the CNT lattice edge. In still further embodiments, ligandbinding sites on the CNT lattice edge may be reacted with metal ionsolutions having variable concentration and pH. The ligand binding sitesmay be pre-existing in certain embodiments, including, but not limitedto, terminal carboxylic acid moieties at the CNT lattice edge. In otherembodiments, a suitable ligand may be synthesized on the CNT latticeedge. One skilled in the art will recognize that certain metal ionsolutions will require pH and reaction temperatures having values in adefined range to efficiently bind to the surface ligands. Furthermore,for a given metal salt, a finite attainable concentration range andchemical compatibility profile will be realized due to the innatephysical properties of the metal salt.

A molecule in an excited state may comprise the fluid phase source ofcarbon atoms for addition to the CNT substrate, wherein increasedreactivity of the excited state carbon source with the CNT substrate isrealized. When the vapor phase contains an excited state species, thecollision rate of the excited state species in the vapor phase may besufficiently low with non-excited state vapor phase molecules so as notto generate extraneous reactive species. In some embodiments, theexcited state is a vibrational excited state. In other embodiments, theexcited state is a radical state. Suitable radical states may include,but are not limited to, C₂H and C₂H₃. In still more embodiments, theexcited state is an excited electronic state. A representative excitedelectronic state molecule is non-dissociatively excited acetylene, whichhas been excited by electromagnetic radiation having a wavelength ofabout 220 nm. One skilled in the art will recognize that other excitedelectronic state molecules can also be utilized within the spirit andscope of the disclosure. The foregoing list of excited state species ismeant to be representative of excited state entities suitable forbringing the disclosure to practice and should not be consideredlimiting for this purpose. One skilled in the art will recognize that anenergetically excited state species having suitable reactivity for agiven application may be generated by a number of techniques andutilized equivalently in the methods described herein. The vapor phasecontaining the excited state carbon species may optionally contain aninert diluent gas and an etchant component. Suitable diluent gases mayinclude, but are not limited to, at least one component selected fromthe group consisting of helium, argon, and nitrogen. Suitable etchantsmay include, but are not limited to, at least one component selectedfrom the group consisting of water, carbon dioxide, ammonia, andhydrogen. In certain embodiments, it may be advantageous to add both theetchant component and inert diluent gas either separately orconcurrently.

In certain embodiments, the rate at which the CNT substrate istranslated away from the CNT templating structure is matched by thegrowth rate of the CNT substrate through addition of carbon atoms. Ifduring addition of atoms to the CNT substrate, the rate at which the CNTtemplating structure and CNT lattice edge are translated apart is tooslow, the CNT substrate will eventually contact the inert support towhich the CNT templating structure is bound. Likewise, if duringaddition of atoms to the CNT substrate, the rate at which the CNTtemplating structure and CNT substrate are translated apart is toorapid, then growth of the CNT substrate will not keep pace with the rateof translation and the CNT substrate will eventually become disconnectedfrom the CNT templating structure.

The rate of carbon atom addition to the CNT substrate may be controlledin several different manners. In one embodiment, the growth rate ofcarbon atom addition to the CNT substrate is controlled by a spatialmodulation of an electromagnetic radiation field, such that thepopulation of excited state carbon-containing fluid phase species at theCNT lattice edge is regulated by the spatial location of the radiationfield relative to the lattice edge. One skilled in the art willrecognize that the population of excited state species may be controlledby the physical location and intensity of the electromagnetic radiationfield, such that the population of excited state species may beregulated to a desired level to give a pre-determined rate of carbonatom addition to the CNT substrate. In embodiments where there istranslation of the CNT substrate, the CNT templating structure, or boththe CNT substrate and CNT templating structure, the radiation field maybe modulated about the axis along which the translation occurs, suchthat as the translation occurs, the population of excited state specieschanges in proportion to the distance between the illumination and theCNT substrate lattice edge. Spatial modulation may therefore be utilizedto control the growth rate of carbon atom addition to the CNT substrateso that the rate of translation is matched by the growth rate of carbonatom addition. A benefit of spatially modulated growth of CNTs is thatdeviations in the growth rate are self-correcting. As such, when thetranslation rate outpaces or falls behind the growth rate, the growthrate adjusts to match. In one embodiment, the exciting radiation is inthe ultraviolet region of the electromagnetic spectrum. In someembodiments, the ultraviolet radiation has an energy of about 3 eV toabout 100 eV. In further embodiments, the ultraviolet radiation has anenergy of about 3.1 eV to 12 eV. In still further embodiments, theultraviolet radiation has an energy of about 3.5 eV to about 5.5 eV. Itwill be understood by one skilled in the art that depending on thespecific molecule being taken to an excited state in a givenapplication, other forms of electromagnetic radiation and excitationwavelengths could be utilized in the spirit and scope of the disclosureto form the spatially modified radiation field.

The fluid phase source of atoms for addition to CNT substrates in thepresent disclosure may be a carbon source dissolved in a molten metal,wherein physical contact is maintained between the molten metal and theCNT substrate. The molten metal is at least one component selected fromperiodic table groups 1-12, the lanthanide elements, and alloys thereof.In some embodiments, the metal may be at least one component selectedfrom the group consisting of Fe, Co, Ni, Au and alloys thereof. In oneembodiment, the carbon source is a solid in contact with the moltenmetal. Such a carbon source may also be preferentially dissolved insteadof the CNT substrate. This feature may be achieved through varioustechniques including but not limited to applying electrical potentialsor by constructing the solid carbon source from a less energeticallystable carbon form, such as amorphous carbon In other embodiments, thecarbon source in the molten metal bath is introduced from a vapor phasecarbon-containing species. One skilled in the art will recognize thatthe vapor phase carbon-containing species may derive from gases,liquids, or solids having low vapor pressures. Said carbon-containingcompounds may contain at least one element other than carbon, and mayinclude, but not be limited to, the group consisting of hydrogen,oxygen, sulfur, nitrogen, fluorine, chlorine, bromine, iodine, siliconand phosphorus. It is well known in the art that presence of otherspecies in a molten metal solution may affect the carbon activity andgrowth mode of carbon deposition from the solution. For example, thepresence of other elements may reduce the surface tension of the moltenmetal bath and lower the interfacial energy between the metal melt andnon-wetting surfaces it contacts. Sulfur and copper are particularlyknown to decrease the surface energy of carbon-containing molten metalmelts, and these elements may optionally be included in the molten metalbaths described herein. Non-metallic elements including, but not limitedto Si and P, may optionally be included in the melt to modify theeffective carbon saturation (activity) and deposition potential. In thepresent disclosure, the carbon-containing species may include, but isnot limited to, at least one component selected from the groupconsisting of methane, ethane, propane, butane, isobutane, 1-butene,cis-2-butene, trans-2-butene, isobutene, ethylene, propene, acetylene,propyne, 1-butyne, 2-butyne, benzene, toluene, carbon monoxide,methanol, ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol,2-methyl-2-propanol, cyclopropane, cyclobutane, acetonitrile,propionitrile, butyronitrile, acetone, butanone, formaldehyde,acetaldehyde, propionaldehyde, and butyraldehyde. In a furtherembodiment of the disclosure, the vapor phase carbon-containing moleculemay be optionally mixed with an inert diluent gas, such that the moltenmetal source is exposed concurrently to both the vapor phasecarbon-containing compound and inert diluent gas. Suitable diluent gasesmay include, but are not limited to, at least one component selectedfrom the group consisting of helium, argon, and nitrogen. In a stillfurther embodiment, the vapor phase carbon-containing molecule may bemixed with an etchant component, such that the molten metal source isexposed concurrently to both the vapor phase carbon-containing compoundand etchant component. In certain embodiments, it is desirable to addboth the etchant component and diluent gas, either concurrently orseparately, along with the carbon-containing compound. Suitable etchantsmay include, but are not limited to, at least one component selectedfrom the group consisting of water, carbon dioxide, ammonia, andhydrogen. More than one CNT may be grown simultaneously from individual,isolated carbon-containing molten metal baths in further embodiments ofthis method.

Molten metal baths are embodied in certain instances wherein one or moremolten metal baths are maintained in individual pits on a refractorysurface. In this embodiment, carbon atoms are added to one or more CNTsubstrates from a carbon atom source through templated growth, while atleast one of the refractory surface and inert support binding the CNTsubstrate is independently translated. In another embodiments of moltenmetal baths, a bulk molten metal bath is maintained on one side of awall of refractory material having a plurality of small (<10 μm) holespenetrating completely through the wall. In other embodiments, themolten metal bath is maintained on both sides of the wall. In additionalembodiments, the molten metal bath resides in the plurality of smallholes. The wall thickness is sufficient to 1) maintain mechanicalintegrity, 2) allow the CNT substrate/CNT template system to reside inthe hole, and 3) allow the growing CNT substrate to extend out of thehole. On the side of the wall opposite the bulk molten metal bath, CNTtemplating structures may be bound to an inert support which isstationary with respect to the refractory material wall. In analternative embodiment of this configuration, the CNT templatingstructures may be bound directly to the refractory surface wall. Ineither configuration, carbon atoms are added to the CNT substrate astranslation occurs using any of the templated growth methods describedherein. In yet another embodiment of molten metal baths, the moltenmetal bath is a bead of molten metal localized at the open end of afreestanding CNT templating structure.

The rate of carbon atom addition to the CNT substrate may be controlledby producing a gradient in the chemical potential of thecarbon-containing vapor phase. In some embodiments, the vapor phaseoptionally contains one or more inert diluent gases or one or moreetchant components in addition to the carbon source. The gradient inchemical potential of the carbon-containing vapor phase exists on theaxis of the CNT substrate along the direction of translation. Thegradient in carbon-containing vapor phase chemical potential ismaintained in these embodiments through independent modulation of thecarbon source comprising the vapor, inert diluent gas in the vapor, andetchant component in the vapor.

The growth rate of the CNT substrates may be controlled by creating agradient of carbon chemical potential in the molten metal baths asdescribed in the disclosure. In one embodiment, the growth rate ofcarbon atom addition to the CNT substrate is controlled by introducingthe carbon-containing vapor at such a rate that a spatial gradient ofcarbon chemical potential exists within the metal bath. In anotherembodiment, the growth rate of carbon atom addition to the CNT substrateis controlled by steps comprising 1) maintaining an etchant componentatmosphere on one side of a refractory substance wall confining a bulkmolten metal bath, wherein a plurality of small (<10 μm) holes penetratecompletely through the wall, and 2) delivering a carbon-containingsource gas on the side of the wall opposite the bulk molten metal bath,wherein one or more CNT templating structures and CNT substrates arepositioned on the side of the wall opposite the bulk molten metal bath;the carbon-containing vapor phase is delivered parallel to the directionof CNT substrate growth; and the carbon-containing vapor phase maintainsa concentration gradient along the direction of CNT substratetranslation through modulation of at least one of the carbon source,inert diluent gas, and etchant component in the vapor. One skilled inthe art will recognize that this spatial arrangement produces a gradientof carbon chemical potential in the molten metal baths at the pointthrough which the bulk molten metal penetrates the wall. Further, askilled artisan will recognize that the chemical potential gradient willcontrol the growth rate of carbon atom addition to the CNT substrate asthe CNT substrate is translated from the CNT templating structure. In afurther embodiment, the diffusion rate of the carbon source into themolten metal bath produces a carbon chemical potential gradient. Thevapor phase carbon-containing species may include, but is not limitedto, at least one component selected from the group consisting ofmethane, ethane, propane, butane, isobutane, 1-butene, cis-2-butene,trans-2-butene, isobutene, ethylene, propene, acetylene, propyne,1-butyne, 2-butyne, benzene, toluene, carbon monoxide, methanol,ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol,2-methyl-2-propanol, cyclopropane, cyclobutane, acetonitrile,propionitrile, butyronitrile, acetone, butanone, formaldehyde,acetaldehyde, propionaldehyde, and butyraldehyde. The inert diluent gasmay include, but is not limited to, at least one component selected fromthe group consisting of helium, argon, and nitrogen. The etchantcomponent may include, but is not limited to, at least one componentselected from the group consisting of water, carbon dioxide, ammonia,and hydrogen. One skilled in the art will recognize that these specificexamples are meant to be illustrative of the disclosure describedherein, and depending on the properties required for a specificapplication, different components or mixtures of components notexplicitly cited may be used to operate within the spirit and scope ofthis disclosure.

In another embodiment of the disclosure provided herein, an electricalpotential is applied to the CNT substrate to produce a reactive carbonspecies from the fluid phase for addition to the CNT substrate. In analternative embodiment, the electrical potential enhances the CNTsubstrate reactivity. In some embodiments, the electrical potential isutilized to produce carbon-containing ionic radicals for addition to theCNT substrate through an electrolytic decomposition reaction of suitablecarbon radical precursors. The carbon-containing ionic radicals mayinclude, but are not limited to, methyl, ethyl, and vinyl radicals.Electrochemical deposition has been previously shown to produce MWCNTs,but the disclosure embodied herein is distinguished from and superior toknown methods in the use of a template to direct CNT growth. Theelectrical potential may also be applied in the presence of anelectrically charged carbon source, which results in attraction of thecharged carbon atom species to the CNT substrate. In a particularembodiment, the charged carbon source may be dissolved in a molten metalsolvent. In another embodiment, the charged carbon source may bedissolved in an ionic liquid solvent. The ionic liquid solvent may be amolten alkali halide or alkaline halide. It has been widely reportedthat alkali metal carbides and alkaline metal carbides are soluble incertain alkali metal halide and alkaline metal halide fused saltsystems. These carbides dissociate to give unbound acetylide (C₂ ⁻²)ions in the molten salt solution. It has been demonstrated that carboncan be electrochemically deposited and redissolved underquasi-reversible conditions in such systems. It has also beendemonstrated that closed graphenic structures are stable in fused alkalihalide salt systems and that these environments are catalytic to therestructuring of graphenic structures into minimum energyconfigurations. The electrical potential may further be applied in thepresence of a neutral and polarizable carbon source, which results inthe establishment of a concentration gradient within the regionthroughout which the neutral and polarizable carbon source is dispersed.

In certain embodiments wherein an electrical potential is applied to aCNT substrate, the CNT templating structure has a lower electricalconductivity than the tip of the growing CNT substrate. In thisinstance, the electric field becomes concentrated at the tip of thegrowing CNT substrate. The electrical potential may be adjusted so thatthe tip of the CNT substrate develops an excess of electron density(i.e., becomes electron rich). When the CNT substrate tip becomeselectron rich, the CNT substrate tip may undergo a Diels-Alder typereaction, wherein the CNT substrate tip serves as the diene component ofthe reaction. Suitable dienophile partners for coupling to the CNTsubstrate diene may include, but are not limited to, vinyl acetic acid,acrylic acid, acrylonitrile and dicyanoacetylene. The electricalpotential may also be adjusted such that the CNT substrate tip developsa net deficiency of electron density (ie., becomes electron poor).Comparable cycloaddition reactions to the electron-deficient CNTsubstrate may be envisioned by those skilled in the art.

An electric field bias may be applied to the growing CNT substrate suchthat the field gradient and charge concentration are varied in thegrowing CNT substrate through choice of electrode geometry. In certainembodiments, the electric field bias may be used to manually regulatethe rate of CNT substrate growth. In other embodiments, the electricfield bias may be used to self-regulate the rate of CNT substrategrowth. Self-regulation of CNT substrate growth may be accomplished bysteps illustrated in FIG. 5 comprising 1) contacting the CNT substrate502 with an electrically insulating template structure 501, eachindividually bound to supports 504 and 505, 2) applying an electricalpotential to CNT substrate 502 through inert support 505, whereinposition 507 is the electrical contact point of CNT substrate 502, andfurther wherein the counter-electrode is in a ring configuration 508surrounding CNT substrate 502 at a distance away from the point ofelectrical contact 507, and 3) adding carbon atoms to CNT substrate 502as 502 is translated in direction 506, such that the rate of carbon atomaddition to CNT substrate 502 is proportional to the electric fieldgradient established at the tip of CNT substrate 502. In certainembodiments, the electrical potential is applied at any point on support505. In additional embodiments, an electrical potential is applied toCNT templating structure 501 through inert support 504. In furtherembodiments, the electrical potential is applied at any point along CNTsubstrate 502. When the electrical contact point is applied along theCNT substrate 502, the site of contact is at point not susceptible toelectrochemical reactions and non-interfering with the electric fieldestablished at the ring counter-electrode. The chosen electrode geometryultimately governs placement of ring electrode 508 in thisconfiguration. In some embodiments, the radius of the ringcounter-electrode determines the distance the ring counter-electrode isplaced away from the point of surface electrical contact 507. Suitableelectrically insulating templates may include, but are not limited toboron nitride nanotubes and large band gap CNTs. In the electrodeorientation embodied in FIG. 5, one skilled in the art will recognizethat the electrical field in the CNT substrate tip is enhanced as thetip nears the ring electrode, thus leading to a self-regulated ratematching of translation to the CNT substrate growth rate.

In another aspect of the disclosure, an electrical potential applied tothe growing CNT substrate enhances the deposition rate of carbon to thegrowing CNT substrate wherein the CNT is translated from an electricallyinsulating template structure which is coaxial and external to the CNTsubstrate in a carbon-atom source environment. Specific examples of theelectrically insulating external template may include, but are notlimited to, boron nitride nanotubes and large band gap CNTs, both ofwhich have a diameter larger than the growing CNT substrate. In oneembodiment of this disclosure, the carbon source is carbon dissolved ina molten metal, wherein the metal is at least one component selectedfrom periodic table groups 1-12, the lanthanide elements, and alloysthereof. In a further embodiment of this method, the metal is moltencobalt.

Another aspect of the disclosure provided herein relates to a method forachieving positional control of CNT substrates by means of aposition-controlling structure contacting the exterior of each CNTsubstrate as it is translated as shown in FIG. 6. Positional control ofgrown CNT substrates is accomplished by steps comprised of 1)positioning a wall structure 605 completely penetrated by one or moreSWCNT conduits 604 between the inert support anchoring point 607 of CNTsubstrate 602 and the CNT substrate lattice edge 603, wherein each CNTsubstrate 602 penetrates wall structure 605 through the interior of aSWCNT conduit 604; the SWCNT conduits 604 are larger than the CNTsubstrate 602 they contain by at least one graphite lattice unitspacing; and the inert support 607 is capable of translational motion,2) growing CNT substrate 602 via templated growth from a fluid phasecarbon source, wherein templating structure 601 is bound to inertsupport 606, and 3) translating the grown CNT substrate 602 through wallstructure 605 separating the fluid phase carbon source from inertsupport 607, wherein translation of CNT substrate 602 is affectedthrough a SWCNT conduit 604. In certain embodiments, the grown CNTsubstrate is translated through the position-controlling structure 604via a spooling motion.

In certain embodiments CNTs may be prepared via templated growth,wherein the CNT substrate lies within the interior of an externaltemplating structure. In this embodiment, the open end of theinternalized CNT substrate may optionally be bonded to a nanoparticle,and the end of the CNT substrate opposite the nanoparticle is attachedto an inert support. In certain embodiments, the internal CNT substratemay be translated through movement of the inert support as atoms areadded to the CNT substrate.

The disclosure herein also describes an embodiment wherein a CNTsimultaneously functions as both a growth substrate and templatingstructure as shown in FIG. 7. In this embodiment, a MWCNT has itsinnermost CNT 701 contacting a templating structure 702, which is boundto inert support 703. As carbon atoms are added to innermost CNT 701during translation of the MWCNT, the innermost CNT 701 serves as atemplate of increasing length to the next layer CNT 704. This processapplies sequentially to all CNTs 704 in the MWCNT until the outermostCNT 705 is reached. The outermost CNT 705 serves only as a growthsubstrate. Templated growth embodied in this sense can be used to createMWCNTs having a beveled tip 700.

The disclosure herein also provides a method for enhancing graphenelattice edge reactivity by exciting non-thermalized excited states inthe graphene lattice edge. In a specific embodiment of this process, amethod for production of CNTs is comprised of 1) placing a preformed CNTsubstrate open on at least one end into proximity of a cylindricaltemplating structure, wherein the CNT substrate contacts the cylindricaltemplating structure within thermal variation and aligns with thecylindrical templating structure in a coaxial fashion within thermalvariation, 2) binding a CNT substrate and cylindrical templatingstructure to separate inert supports, wherein each support may beindependently translated, 3) producing non-thermalized excited states ina CNT substrate, and 4) depositing carbon from a fluid phase to the openend of a CNT substrate where the CNT substrate lattice edge contacts thecylindrical templating structure, while at least one of the CNTsubstrate or cylindrical templating structure is translated during thedepositing. In some embodiments, the CNT lattice edge is brought into anon-thermalized excited state through direct excitation of edgelocalized states. In polyaromatic systems, “zig-zag” configurations areknown to have localized electron sites which populate the Dirac point inthe density of states. Transitions from these edge localized statesallow the direct excitation of non-thermalized states at the CNT latticeedge to enhance reactivity. The edge localized states may include, butare not limited to, benzyne and carbyne sites on the CNT lattice edge.In other embodiments, plasmon excitation of the CNT substrate producesnon-thermalized edge state excitation. In certain embodiments, UVirradiation produces a CNT lattice edge substrate having non-thermalizedexcited states.

The CNT substrate reactivity toward carbon atom addition may also beenhanced by exciting non-thermalized excited states in CNT substratesbound to at least one metal atom. The metal atoms may be at least onecomponent chosen from periodic table groups 3-12, the lanthanideelements, and combinations thereof. The non-thermalized excited statemay be produced through excitation of the metal-carbon bond.Alternatively, the non-thermalized excited state may be produced throughdirect excitation of the metal atom, including, but not limited to,interaction of the metal atom with X-rays.

EXPERIMENTAL EXAMPLES Prophetic Example 1 Acetylides in Alkali HalideFused Salts

A fused molten salt environment comprised of one or more alkali metalhalides will be prepared, wherein the cationic alkali metal species willbe chosen from Li, Na, and K and the anionic halogen component will bechosen from F, Cl, and Br. Feedstock species comprised of at least onealkali acetylide, alkaline acetylide, or a combination thereof willthereafter be prepared in the molten alkali halide solvent. A graphenicsubstrate/templating system will be brought into contact in the moltenalkali halide solvent, and the graphenic sub strate/templating systemwill be translated apart as carbon is electrochemically added to thegraphenic substrate under quasi-equilibrium conditions. The reactiontemperature will be sufficient to render the solvent composition liquidand provide activation energy sufficient to anneal deposited carbon.Other carbon sources are envisioned to be utilized in this method,including, but not limited to, alkali metal carbonates. A method togenerate carbide ions in situ from a carbon electrode or from externalacetylene bubbled over the cathode are also envisioned. In general thepotential required to deposit carbon at quasi-equilibrium conditionswill depend upon the salt system, temperature and counter-electrode, andwill be directly found through a standard CV (cyclic voltammetry)experiment to identify the acetylide oxidation potential. In general theworking electrode will be the graphenic material templated growthsystem. The counter (auxiliary) and reference electrodes will simply becompatible with the cell; that is they will be stable in and notcontaminate the molten alkali halide environment, and they will notdegrade during the reduction of alkali ions.

Prophetic Example 2 Iron/Cobalt Alloy Solvent System

The ability of certain transition metals to dissolve carbon withoutforming stable carbides is well known in metallurgy and widely exploitedin the synthesis of carbon nanomaterials such as CNTs.

A molten metal ternary alloy comprised of cobalt, iron, and carbon willbe prepared and liquified between about 1115-1135° C. The ratio ofcobalt to iron in the ternary alloy will be between about 3:17 to about3:7. The carbon concentration in the ternary alloy will be about 14 toabout 17 atomic percent. Carbon saturation will be achieved by placingthe molten cobalt/iron alloy in contact with a carbon source, includingbut not limited to amorphous carbon. Once the ternary allow has beenestablished and temperature adjusted to 1115-1135° C., a graphenicsubstrate/templating system will be brought into contact in the moltenalloy. The environmental pressure will be maintained below atmosphericpressure and ideally will be maintained between 10-400 torr to avoidincreasing the likelihood of diamondoid carbon formation while keepingthe molten metal bath from evaporating. The temperature will be raisedto slightly above these conditions (1150° C.), and carbon will then bedeposited into the graphenic substrate when the carbon chemicalpotential is just above saturation. As the graphenic substrate isextended, translation will be performed to maintain the graphenicsubstrate and templating structure in contact with one another. Thesolvent system will be maintained at near equilibrium carbon saturationconditions to deliver templated growth of highly perfect graphenicmaterials.

1. A method for production of a structured material, comprising placinga preformed substrate in contact with a templating structure; providinga reactive source of atoms from a fluid phase; depositing atoms from thefluid phase to the preformed substrate; and translating at least one ofthe preformed substrate and the templating structure during thedepositing, while maintaining the contact, so as to grow the preformedsubstrate in to the structured material.
 2. The method of claim 1,wherein the structured material comprises a graphenic material.
 3. Amethod for production of a CNT, comprising placing a preformed CNTsubstrate open on at least one end in contact with a cylindricaltemplating structure; providing a reactive source of carbon in a fluidphase; depositing carbon from the fluid phase to the open end of saidCNT substrate; and, translating at least one of said CNT substrate andsaid cylindrical templating structure during the depositing, whilemaintaining the contact.
 4. The method of claim 3, wherein thecylindrical templating structure contacts the exterior of the CNTsubstrate.
 5. The method of claim 4, wherein (a) the open end of the CNTsubstrate lies within the interior of the external templating structure,(b) the open end of the CNT substrate is bonded to a nanoparticle, and(c) the end of the CNT opposite that bonded to the nanoparticle isattached to an inert support.
 6. The method of claim 3, wherein at leastone metal atom selected from the group consisting of periodic tableGroups 3-12, the lanthanide elements, and combinations thereof is bondedto the open end of the CNT substrate.
 7. The method of claim 6, whereinthe metal atoms are attached to the CNT lattice edge by electrochemicaldeposition.
 8. The method of claim 3, wherein an electric potential isapplied to the CNT substrate.
 9. The method of claim 8, wherein thetemplate structure has a lower electrical conductivity than the tip ofthe growing CNT substrate.
 10. The method of claim 3, wherein aposition-controlling structure contacts the exterior of each CNTsubstrate as it is translated.
 11. The method of claim 10, whereinpositional control of a CNT substrate is achieved by steps comprised of(a) positioning a wall structure completely penetrated by a SWCNTconduit between the inert support anchor point of the CNT substrate andthe CNT substrate lattice edge, wherein (a1) a CNT substrate penetratesthe wall structure, each through the interior of a SWCNT conduit, (a2)said SWCNT conduits are larger than the CNT substrate they contain by atleast one graphite lattice unit spacing, and (a3) the inert support iscapable of translational motion; (b) growing the CNT substrate viatemplated growth from a fluid phase carbon source; and (c) translatingthe grown CNT substrate through a SWCNT conduit.
 12. The method of claim11, wherein translation of the grown CNT substrate is achieved through aspooling motion.
 13. The method of claim 3, wherein a CNT simultaneouslyfunctions as a growth substrate and template.
 14. A method forproduction of a CNT, comprising placing a preformed CNT substrate openon at least one end in contact with a cylindrical templating structure,wherein said CNT substrate contacts said cylindrical templatingstructure within thermal variation, and aligns with said cylindricaltemplating structure in a coaxial fashion within thermal variation.